KR200156601Y1 - Apparatus for removing defrost water of refrigeration system - Google Patents

Abstract

The disclosed dew condensation water removing device detects the water level of the defrost water collected in the evaporation vessel and evaporates when the defrost water is above the set water level, so that the evaporation efficiency of the defrost water is high and does not overflow the evaporation vessel.

The present invention includes an evaporation heater on the bottom surface of the evaporator, a water level sensor for detecting the water level of the defrost water inside the evaporator, and the water level when the water level of the defrost water detected by the water level sensor is more than the predetermined level The signal of the sensor causes the evaporation control unit to heat the evaporation heater, and as the defrost water is heated and evaporated according to the evaporation of the evaporator heater, the defrost water level decreases as the defrost water is heated and evaporated, and then decreases below the preset level. In this case, the evaporation control unit stops the evaporation heater by the signal of the water level sensor to stop the evaporation operation of the defrost water.

Description

Condensate removal device of refrigeration system

The present invention relates to a condensation water removing apparatus of a refrigeration system for evaporating and removing condensed water in a refrigeration system having a refrigerating cycle such as a refrigerator and various showcases.

Generally, refrigeration / refrigeration devices that freeze and / or refrigerate certain foods have refrigeration cycles that generate cold air.

1 is a view showing the configuration of a general refrigeration cycle.

Here, reference numeral 1 denotes a compressor for compressing a refrigerant, and reference numeral 2 denotes a condenser for condensing the refrigerant compressed by the compressor 1.

The refrigerant condensed in the condenser 2 is connected to flow into the compressor 1 after being evaporated in the evaporator 4 through the capillary tube 3.

In the refrigeration cycle configured as described above, the refrigerant is compressed in the compressor 1 and converted into a gas refrigerant having a high temperature and high pressure.

The high temperature and high pressure gas refrigerant compressed by the compressor (1) is condensed while being exchanged with cooling water or external air in the condenser (2) and converted into a liquid refrigerant of room temperature and high pressure is discharged.

The liquid refrigerant at room temperature and high pressure condensed in the condenser 2 is reduced in pressure by passing through the capillary tube 3, and is converted to the liquid refrigerant at room temperature and low pressure, and is evaporated in the evaporator 4 to generate cold air.

That is, the liquid refrigerant of normal temperature and low pressure reduced in the capillary tube 3 expands in the evaporator 4 and is converted into gas refrigerant of low temperature and low pressure to generate cold air, and the cold low pressure refrigerant, which generates cold air, flows back into the compressor 1. To be compressed into a gaseous refrigerant of high temperature and high pressure.

The refrigeration system having such a refrigeration cycle is frosted in the vicinity of the freezer compartment and the evaporator 4 by the cold air generated in the evaporator.

It is preferable to remove the frost since the efficiency of cold air generation of the evaporator 4 is lowered.

In order to remove frost generated near the freezer compartment and the evaporator 4, a defrost heater is usually provided, and when the compressor 1 is driven for a predetermined time, the defrost heater is defrosted by generating heat for a predetermined time. .

Condensation water from which defrosting is removed by heating the defrost heater is generally collected in an evaporation vessel through a drain hose, and the collected condensation water is heated and evaporated.

2 is a schematic view showing a conventional condensation water removing apparatus for removing condensation water collected in an evaporation vessel.

Here, reference numeral 10 denotes an evaporation vessel.

The drain hose 11 for collecting condensation water from which defrosting is removed and introduced into the evaporation vessel 10 is located at the upper portion of the evaporation vessel 10.

In addition, a refrigerant tube 12 through which a high temperature and high pressure gas refrigerant compressed by the compressor 1 passes is installed inside the evaporation vessel 10, and a cloth 13 such as a nonwoven fabric is wound around the refrigerant tube 12. It is configured to be in contact with the bottom surface of the evaporation vessel (10).

In the conventional condensation water removing device configured as described above, defrost water from which defrosting is removed while the defrost heater is heated is collected into the evaporation vessel 10 through the drain hose 11.

The defrost water collected in the evaporator 10 is wetted with a cloth 13.

When the compressor 1 is driven in such a state, the high temperature and high pressure gas refrigerant compressed by the compressor 1 passes through the refrigerant pipe 12.

Then, the defrost water buried in the cloth 13 is heated and evaporated while being exchanged with the high temperature and high pressure gas refrigerant passing through the refrigerant pipe 12.

However, in the above-described conventional technique, when the cloth 13 is deteriorated when used for a long time, and the defrosting water has a low evaporation efficiency, the defrost water frequently overflows the evaporation vessel 10, and thus the reliability of the product is deteriorated. There was a problem.

Accordingly, an object of the present invention is to provide a condensation water removing device of a refrigeration system that has high evaporation efficiency of defrost water and does not overflow an evaporation vessel.

Another object of the present invention is to provide a condensation water removal device of a refrigeration system that detects the water level of the defrost water collected in the evaporator, and evaporates the defrost water when it is above the set water level.

1 is a view showing the configuration of a typical refrigeration cycle,

2 is a schematic view showing a conventional condensation water removing device,

3 is a partial cutaway cross-sectional view showing a condensation water removing device of the present invention,

4 is a control circuit diagram of the condensation water removing device of the present invention.

Explanation of symbols on the main parts of the drawings

100: evaporation container 110: drain hose

120: evaporation container 130: water level sensor

131: vertical support rod 132: ball

133, 134: reed switch 140: evaporation control

141: flip-flop TR: transistor

RY: Relay Coil RYS: Relay Switch

According to the condensation water removing apparatus of the present invention for achieving the above object, the lower surface of the evaporator is provided with an evaporator, and the inside of the evaporator is provided with a water level sensor for detecting the water level of the defrost water.

When the level of the defrost water detected by the water level sensor is greater than or equal to a predetermined level, the evaporation controller generates the evaporation heater by the signal of the water level sensor, and the defrost water is heated and evaporated according to the heat generated by the evaporation heater.

As the defrost water is heated and evaporated, the water level of the defrost water is reduced, and when the water level is lowered below the preset level, the evaporation controller stops the evaporation operation of the defrost water by the signal of the water level sensor.

Hereinafter, the condensation water removing device of the refrigeration system of the present invention will be described in detail with reference to the accompanying drawings of FIGS. 3 and 4.

3 is a partial cutaway cross-sectional view showing a condensation water removing device of the present invention.

Here, 100 is an evaporation tank in which defrosting defrosted water is collected through the drain hose 110.

An evaporation heater 120 is provided below the evaporation vessel 100 to evaporate and remove the defrost water collected in the evaporation vessel 100.

And the inside of the evaporator 100 is provided with a water level sensor 130 for detecting the water level of the defrost water.

The water level sensor 130, the vertical support rod 131 is installed in the evaporation vessel 100, the outside of the vertical support rod 131 is provided with a float 132 provided with a permanent magnet (not shown in the figure) And is raised and lowered according to the condensation water level, and a reed switch 133 connected to the inside of the vertical support bar 131 by magnetic lines of force of the sub-ball 132 when the water level of the defrost water is the highest water level and the lowest water level. 134 is provided.

4 is a control circuit diagram of the condensation water removing device of the present invention.

As shown therein, the power source B1 + is connected to be applied to one terminal of the reed switch 133 for detecting the highest level of the defrost water and the reed switch 134 for detecting the lowest level of the defrost water.

The other terminals of the reed switches 133 and 134 are respectively connected to the set terminal SE and the reset terminal RE of the flip-flop 141 through the resistors R1 and R2, respectively. The output terminal Q of 141 is connected to the base of the transistor TR.

A relay coil RY and a diode D1 are connected to the collector of the transistor TR, and a power source B2 + is connected to be applied to the evaporation heater 120 through a relay switch RYS, so that the evaporation controller 140 is connected. Is composed.

In the above, the relay switch RYS is connected when the relay RY is driven.

In the condensation water removing device of the present invention configured as described above, frost generated according to the operation of the refrigeration cycle in the state where power (B1 +) (B2 +) is applied is collected in the evaporator 100 through the drain hose 110.

In this state, according to the water level of the defrost water collected in the evaporator 100, the float 132 of the water level sensor 130 rises, and when the defrost water level reaches the highest level, the float 132 is Since it is located outside the reed switch 133, the reed switch 133 is connected by a magnetic force line generated in the sub-ball 132.

When the reed switch 133 is connected, the power source B1 + is applied to the set terminal SE of the flip-flop 141 through the reed switch 133 and the resistor R1 of the evaporation controller 140, thereby providing a flip-flop ( 141 is set to output the high potential to the output terminal Q.

The transistor TR is turned on according to the high potential output by the flip-flop 141, and the relay coil RY is driven so that the relay switch RYS is connected.

Then, since the power source B2 + is applied to the evaporation heater 120 through the relay switch RYS, the evaporation heater 120 generates heat to heat the evaporation vessel 100, and the condensation water collected in the evaporation vessel 100. Is evaporated and removed.

Here, in order to increase the evaporation efficiency of the defrost water of the evaporation vessel 100, the heat of the evaporation heater 120 should be smoothly transferred to the defrost water.

Therefore, in the present invention, it is preferable to manufacture the evaporation vessel 100 with a metal having high heat transfer efficiency.

In this state, as the condensation water collected in the evaporation vessel 100 is continuously evaporated and removed, the condensation water level of the evaporation vessel 100 is lowered, and the reed switch 133 is opened again because the float 132 is lowered. do.

At this time, even when the reed switch 133 is opened, the flip-flop 141 continues to set and outputs a high potential to the output terminal Q, so that the transistor TR is continuously turned on and the defrost heater 120 generates heat. It will continue to evaporate the condensation water of the evaporation vessel (100).

In this state, when the water level of the condensation water in the evaporation vessel 100 becomes below the minimum level, the magnetic lines generated in the float 132 are located at the outside of the reed switch 134 for detecting the minimum level. The reed switch 134 is connected by this.

When the reed switch 134 is connected, the power source B1 + is applied to the reset terminal RE of the flip-flop 141 through the reed switch 134 and the resistor R4 of the evaporation controller 140, thereby flipping the flop. 141 is reset to output a low potential to the output terminal Q.

Then, contrary to the above, since the transistor TR is turned off and the relay coil RY is not driven and the relay switch RYS is opened, the heat generation of the evaporation heater 120 is stopped and the evaporation operation of the dew condensation water is stopped.

Here, the diode D1 is for removing the surge voltage generated when the driving of the relay coil RY is stopped.

As described above, the present invention is provided with an evaporator in the evaporator, and when the condensation water collected in the evaporator is above the set level, the evaporator is heated to evaporate the condensed water without deterioration even after long-term use. The condensation water can be evaporated and removed smoothly, and the condensation water can be prevented from overflowing the evaporator.

Claims (5)

An evaporation vessel in which condensation water is collected; A water level sensor for detecting the water level of the condensation water collected in the evaporation vessel; An evaporator for evaporating the condensed water collected in the evaporator; And A refrigeration system comprising: an evaporation control unit configured to evaporate the condensation water by heating the evaporation heater when the water level sensor detects a predetermined high water level or more and to stop the evaporation heater when detecting the preset low water level. Condensation water removal device. The method of claim 1, wherein the evaporator barrel; Decondensation water removal device of the refrigeration system, characterized in that the high thermal conductivity of the metal. The water level sensor according to claim 1, wherein the water level sensor; Buoys having magnetic lines ascending and descending in accordance with the condensation water level; A maximum water level reed switch connected when said float rises to a predetermined maximum water level; And Condensation water removal device of the refrigeration system, characterized in that consisting of a reed switch for the lowest water level is connected when the buoy is lowered to a predetermined minimum water level. The water level sensor according to claim 3, wherein the water level sensor; And a vertical support rod for guiding the lifting and lowering of the float, and the highest water level reed switch and the lowest water level reed switch are installed in the vertical support rod. The method of claim 1, wherein the evaporation control unit; A flip-flop set when the water level sensor detects the highest water level and reset when detecting the lowest water level; A transistor turned on when the flip-flop is set; And And a relay coil and a relay switch operating when the transistor is turned on to generate the evaporation heater.